DE112015006241B4 - Valve device - Google Patents

Abstract

The invention relates to a valve device (10; 20; 30; 40) comprising: a channel (2) for guiding a fluid (3); a valve body (5) which is arranged in the channel (2); a first coupling arrangement (4) which is assigned to the channel (2), and a second coupling arrangement (6) which is assigned to the valve body (5), one of the two coupling arrangements comprising a magnet arrangement (11; 12) and the other comprising the two coupling arrangements comprises a superconductor arrangement (13), and the magnet arrangement (11; 12) and the superconductor arrangement (13) are coupled to one another in a contactless force-transmitting manner in order to ensure a pivotable mounting of the valve body (5) relative to the channel (2); a drive means (7) for, in particular contactless, providing an actuating force on the valve body (5) in order to pivot it relative to the channel (2) between a first position and a second position and thereby to influence a free cross section of the channel (2) .

Description

The invention relates to a valve device with a channel and a valve body which is designed to influence a free cross section of the channel by a movement of the valve body relative to the channel.

Valve devices are known from the prior art in which a valve body located in the channel is mechanically connected to a drive means arranged outside the channel and can be moved by this relative to the channel.

JP H01-193 471 discloses a ball valve with a disk-shaped superconductor in a position eccentric to the center of the ball and a tubular electromagnet near the ball valve in corresponding outlets, the disk-like superconductor being arranged in an eccentric position inside the ball valve in a funnel-like through hole . A valve housing is provided with an inlet on the diverging side of the through hole and a plurality of outlets on the opposite side. Electromagnets, which are directed towards the center of the ball valve, are arranged near the ball valve at the respective outlets and, when supplied with power, generate the Meissner effect in order to change the position of the ball valve.

The DE 199 59 299 A1 discloses a device for treating objects with a medium, comprising a container for receiving the medium, a rotatable support device arranged at least partially in the container for receiving the objects to be treated and a support device stored in at least one store with the support device connected, rotatably drivable shaft, wherein the bearing has a first bearing part connected to the shaft and a second bearing part adjacent to the first bearing part and containing a superconducting material, the first bearing part opposite the second bearing part by magnetic Forces is kept spaced.

From the US 2014 019 26 13 A1 a pumping system is known in which a cryostat is used to cool a superconducting element that causes levitation in a pumping or mixing element. The pumping or mixing element is located in a container that is located outside the cryostat. The container can already contain a liquid or can be filled after the pumping or mixing element has been introduced. The pumping or mixing element comprises a first permanent magnet which is designed for positioning in the container next to the superconducting element arranged outside the container in such a way that the pumping or mixing element floats in the liquid F.

The JP H04 008 977 A discloses a 5-axis magnetic bearing with radial magnetic bearings and an axial magnetic bearing, wherein a play between a valve seat and a valve body and a play between a rotating shaft and a housing can be detected on the basis of signals from displacement sensors. To regulate this bearing, excitation currents from electromagnetic excitation coils are influenced by a phase compensation circuit and a power amplifier in order to maintain predefinable distances. The valve body and the rotating shaft are magnetically mounted in a floating manner and held in a non-contact state with respect to a valve seat and a housing. In order to close the valve, the radial bearings are controlled in such a way that they turn the valve body by 90 °, whereby it is aligned eccentrically to the through hole and the flow of the liquid is interrupted.

It is an object of the present invention to provide an improved valve device which can be used flexibly.

This object is achieved according to the invention by a valve device which comprises a channel for guiding a fluid, a valve body which is arranged in the channel, a first coupling arrangement which is assigned to the channel, and a second coupling arrangement which is assigned to the valve body. One of the two coupling arrangements comprises a magnet arrangement and the other of the two coupling arrangements comprises a superconductor arrangement. The magnet arrangement and the superconductor arrangement are coupled to one another in a non-contacting manner in a force-transmitting manner in order to ensure that the valve body is pivotably supported relative to the channel. The valve device also comprises a drive means for, in particular contactless, providing an actuating force on the valve body in order to pivot it relative to the channel between a first position and a second position and thereby to influence a free cross section of the channel. Preferably, the valve body can be pivoted into any number of other positions between the first and second positions.

According to the present invention, the valve body is firstly mounted in a pivotable manner in the channel by a contactless force-transmitting coupling and secondly moved by pivoting between two or more different positions. The combination of these two aspects according to the invention, as explained in more detail below, has the particular advantage that the valve device can be used flexibly.

First, in the valve device according to the invention, a contactless force-transmitting coupling is achieved via the interaction between a magnet arrangement and a superconductor arrangement and the magnetic interactions caused thereby. Because of this contactless force-transmitting coupling of the coupling arrangements and the resulting magnetic mounting of the valve body, it is not necessary in the valve device according to the invention to provide a mechanical bearing for the valve body, and thus it is also not necessary to provide appropriate fastening elements and seals on the inner wall of the channel. The channel of the valve device according to the invention therefore does not require a specially designed inner wall.

Furthermore, due to the pivoting of the valve body, which is to be initiated contactlessly from the outside, it is possible to influence the free cross section of the channel without the valve body having to be pushed out of the channel in one of the positions as with a slide valve. The valve body can thus remain completely in the channel in both, preferably in all, positions. In contrast to this, if a pure displacement of the valve body is used to influence the free cross section, a special chamber must generally be provided into which the valve body can be moved in one of the two positions. Such a chamber is not absolutely necessary in the valve body according to the invention because of the claimed pivoting.

As a result, the inventive combination of the two aspects discussed - namely that the valve body is pivotably mounted by a contactless force-transmitting coupling and assumes various positions through a pivoting movement - a channel can be used whose inner channel wall does not have to be designed in any special way. This can facilitate the production of the channel of the valve device according to the invention. Furthermore, the valve body can hereby be used very flexibly. For example, by introducing the valve body into an existing channel system, it is possible to implement a valve device on a desired section of the channel system without having to separate the existing channel system and / or without performing additional work on the channel system such as drilling or the like. Since there are no special requirements for the channel of the valve device according to the invention, it is possible to simply use a channel section of an existing channel system as the channel of the valve device. For this purpose, the first coupling arrangement and the drive means can be attached to the outside of the channel section, and the valve body can then simply be inserted into the channel system so that, driven by the fluid flow and / or gravity, it moves through the channel system up to the Channel section moved with the coupling arrangement, where it is then held by the contactless force-transmitting coupling between the magnet arrangement and the superconductor arrangement and is pivotably mounted. Consequently, the valve device according to the invention can be used particularly flexibly.

In addition, in contrast to conventional valve devices, the valve device according to the invention has no mechanical bearing, such as a sliding or roller bearing, and thus achieves the advantages that on the one hand there is less or no wear and on the other hand there is no mechanical bearing in the channel is present, and no sealing of such a mechanical bearing is required to prevent the fluid flowing through the channel from escaping.

The claimed pivotable mounting of the valve body relative to the channel can be achieved by a magnetic interaction between the two coupling arrangements which excludes at least two degrees of translational freedom and two degrees of freedom of rotation. Appropriately, at least one degree of translational freedom and / or one degree of freedom of rotation can also be excluded by supporting the valve body on the channel. It is crucial that the mounting of the valve body enables the valve body to pivot relative to the channel; This means that a degree of freedom of rotation is allowed between the valve body and the channel, so that the valve body can be pivoted between the different positions.

The claimed contactless force-transmitting coupling between the magnet arrangement and the superconductor arrangement can be achieved, for example, by using the so-called flux pinning or flux anchoring effect in a superconductor. With this effect, a certain magnetic field geometry / flux distribution is programmed or stored in a superconductor, so to speak, so that the superconductor then preferably assumes that position relative to a magnetic field in which the geometry of the magnetic field penetrating the superconductor most closely matches the magnetic field geometry stored in the superconductor. Superconductors of the second type, such as ceramic high-temperature superconductors, are particularly suitable for using this effect. Examples of such superconductors are YBaCuO (yttrium-barium-copper oxide) and BiSrCaCuO (bismuth-strontium-calcium-copper oxide).

The storage of the magnetic field geometry in the superconductor arrangement can thereby take place that initially the magnet arrangement is arranged in the desired spatial position opposite the superconductor arrangement, the superconductor arrangement having a temperature above its critical temperature at this point in time. The superconductor arrangement is then cooled to its critical temperature or below, so that the magnetic field provided by the magnet arrangement is stored in the superconductor arrangement. If the critical temperature for the superconductor arrangement is maintained, a change in the spatial position of the magnet arrangement with respect to the superconductor arrangement leads to reaction forces, so that a desired spatial relationship between the magnet arrangement and the superconductor arrangement can be maintained without contact.

The first coupling arrangement which is assigned to the channel can expediently be attached to the outside of the channel. The first coupling arrangement can be attached to the outside of the channel in a movable or fixed manner, depending on requirements. Alternatively, it is of course also possible for the first coupling arrangement to be embedded in the wall of the channel so that it is arranged as close as possible to the valve body in order to achieve a very strong coupling between the two coupling arrangements.

The second coupling arrangement, which is assigned to the valve body, can be attached to the latter. Alternatively, the second coupling arrangement and the valve body can also be designed as a one-piece element. Furthermore, the entire valve body can of course also function as the second coupling arrangement.

The free cross-section of the channel can be influenced in such a way that the free cross-section is increased or decreased when the valve body is pivoted from one position to another. The free cross section can in particular be a cut surface of the channel which is normal to the direction of flow of the fluid.

The device according to the invention can preferably also be designed as a filter and valve device. The valve body can be designed as a filter body and / or comprise corresponding filter elements, such as a sieve or a sieve-like structure. In addition or as an alternative to this, a filter functionality can also be provided in that the valve body is held in one or more of the positions at a predetermined distance from the inner wall of the duct.

Advantageous further developments of the invention are the subject of the dependent claims.

In one embodiment of the invention, it is provided that the first and second coupling arrangements form a pivot bearing with an axis of rotation for the valve body, so that the valve body is pivoted about the axis of rotation when the coupling arrangements move relative to one another.

For this purpose, an essentially circularly symmetrical magnetic field geometry is expediently stored or programmed into the superconductor arrangement, and a corresponding circularly symmetrical magnetic field is provided by the magnet arrangement. If the magnet arrangement and the superconductor arrangement are now aligned with one another in such a way that the magnetic field provided and the stored or programmed magnetic field geometry are essentially coaxial with one another, the superconductor arrangement always experiences essentially the same magnetic field even when rotating around the axis of symmetry of the stored magnetic field geometry or the magnetic field provided relative to the stored magnetic field geometry. Accordingly, such a rotation is not opposed by any substantial forces caused by the coupling between the magnet arrangement and the superconductor arrangement. Consequently, a rotary bearing can be provided, the axis of rotation of which essentially corresponds to the axis of symmetry of the stored magnetic field geometry or of the magnetic field provided.

In a further embodiment of the invention it is provided that the second coupling arrangement comprises at least one circularly symmetrical permanent magnet and / or at least one section of a circularly symmetrical permanent magnet as the magnet assembly.

By means of such magnet arrangements, an essentially circularly symmetrical magnetic field can be provided in a simple manner, by means of which, for example, the above-discussed rotary bearing between the first and second coupling arrangement can be achieved. For example, one or more ring magnets and / or cutouts from ring magnets can be used for this purpose. Furthermore, in this embodiment the magnet arrangement is assigned to the valve body and consequently the superconductor arrangement is assigned to the channel. This is advantageous since the superconductor arrangement can be cooled more easily outside the channel.

In a further embodiment of the invention it is provided that the first coupling arrangement comprises an electromagnet arrangement and / or a permanent magnet arrangement as the magnet arrangement.

In this embodiment, the magnet arrangement is assigned to the channel, and consequently the superconductor arrangement is assigned to the valve body. This is particularly advantageous if the fluid flowing through the channel has such a low temperature that the superconductor arrangement is cooled to or below the transition temperature required for the superconducting state. Furthermore, if the magnet arrangement is designed as an electromagnet arrangement, the magnetic field provided can be controlled, whereby the mounting of the valve body can be actively adapted.

In a further embodiment of the invention it is provided that the drive means is set up to provide a magnetic field which at least partially penetrates the valve body as a function of a control signal.

This embodiment is particularly advantageous when a rotary bearing is provided between the two coupling arrangements, as discussed above. Since in this case the valve body can rotate relative to the first coupling arrangement, it is necessary to provide a torque on the valve body in order to bring about a desired pivoting of the valve body. This provision preferably takes place in a contactless manner, for example in that the drive means is set up to provide a magnetic field which causes a magnetic interaction with at least one component of the valve body, so that the torque required for the pivoting can be provided on the valve body.

In a further embodiment of the invention it is provided that at least one component assigned to the valve body has magnetic properties, so that the magnetic field provided by the drive means exerts the actuating force on the valve body.

For example, the valve body or the second coupling arrangement can include the component with the magnetic properties.

In a further embodiment of the invention it is provided that the first coupling arrangement and the second coupling arrangement are rotatably coupled to one another, and the drive means are set up to pivot the first coupling arrangement relative to the channel as a function of a control signal in order to effect the pivoting of the valve body.

In contrast to the embodiments of the invention discussed above, in which the first and second coupling arrangements function as rotary bearings, in this embodiment the first and second coupling arrangements are coupled to one another in a rotationally fixed manner. For example, all degrees of freedom of movement between the coupling arrangements can be excluded by the coupling. For this purpose, the superconductor arrangement is preferably designed in such a way that there is an essentially rigid coupling between the superconductor arrangement and the magnet arrangement. This essentially rigid coupling is achieved by suitable magnetization of the at least one magnet arrangement and corresponding storage of the magnetic field geometry of the magnet arrangement in the superconductor. The magnet arrangement preferably provides a magnetic field that is not uniform in any of the three spatial directions, so that when this magnetic field geometry is stored in the superconductor, which can occur when the superconductor cools to or below its critical temperature, a clear spatial association between the magnet arrangement and the superconductor assembly is achieved.

This makes it possible to adjust the position of the valve body directly by changing the position of the first coupling arrangement. In particular, it is possible to pivot the valve body directly by pivoting the first coupling arrangement. For this, for example, the drive means can comprise a rotary motor which is connected to the first coupling arrangement via a shaft in order to pivot the first coupling arrangement relative to the channel, which in turn leads to a pivoting of the second coupling arrangement and thus to a change in the position of the valve body relative to the channel leads. This procedure has the advantage that no further magnetic field is required to effect the pivoting movement of the valve body.

In a further embodiment of the invention it is provided that the superconductor arrangement comprises at least one plate-shaped superconductor which is at least partially arranged within a magnetic field provided by the magnet arrangement.

Plate-shaped superconductors are well suited to provide a contactless, fixed coupling to a magnet arrangement by means of the flux pinning effect discussed above. The plate-shaped superconductor is preferably arranged in such a way that the magnetic field of the magnet arrangement penetrates it normal to the plane of the plate.

In a further embodiment of the invention, it is provided that the valve body rests against the channel in the first position and / or the second position, so that the valve body is mounted in a stable manner in the first position and / or the second position.

In this way, a very simple, stable mounting of the valve body in the first and / or second position can be achieved. In particular in the embodiment discussed above, in which the two coupling arrangements form a pivot bearing, and the drive means is set up to apply a torque about the axis of rotation to the valve body, stable mounting of the valve body in the corresponding position can be achieved by resting or supporting the valve body on the channel.

In a further embodiment of the invention it is provided that the valve body comprises at least one sealing lip which rests against the channel in the first and / or second position so that the channel is closed in one of the two positions.

• 1 eine schematische Draufsicht auf eine erste Ausführungsform einer Ventilvorrichtung, wobei eine Magnetanordnung dem Ventilkörper zugeordnet ist, eine erste und eine zweite Koppelanordnung ein Drehlager bilden und sich der Ventilkörper in einer ersten Stellung relativ zum Kanal befindet,
• 2 eine schematische Draufsicht der in 1 gezeigten ersten Ausführungsform einer Ventilvorrichtung, wobei sich der Ventilkörper in einer zweiten Stellung relativ zum Kanal befindet,
• 3 eine schematische Seitenansicht der in 1 gezeigten ersten Ausführungsform einer Ventilvorrichtung,
• 4 eine schematische Seitenansicht auf eine zweite Ausführungsform einer Ventilvorrichtung, wobei die Magnetanordnung außen am Kanal angeordnet ist und die erste und zweite Koppelanordnung ein Drehlager bilden,
• 5 eine schematische Draufsicht einer dritten Ausführungsform einer Ventilvorrichtung, wobei die erste und zweite Koppelanordnung drehfest miteinander gekoppelt sind,
• 6 eine schematische Seitenansicht der in 5 gezeigten dritten Ausführungsform einer Ventilvorrichtung,
• 7 eine schematische Seitenansicht einer vierten Ausführungsform einer Ventilvorrichtung, wobei der Ventilkörper Dichtlippen umfasst und die Supraleiteranordnung in der Kanalwandung eingelassen ist,
• 8 eine schematische Draufsicht der in 7 gezeigten vierten Ausführungsform einer Ventilvorrichtung.

Advantageous embodiments of the invention are shown in the drawing. It shows

• 1 a schematic plan view of a first embodiment of a valve device, wherein a magnet arrangement is assigned to the valve body, a first and a second coupling arrangement form a pivot bearing and the valve body is in a first position relative to the channel,
• 2 a schematic plan view of the in 1 shown first embodiment of a valve device, wherein the valve body is in a second position relative to the channel,
• 3 a schematic side view of the in 1 shown first embodiment of a valve device,
• 4th a schematic side view of a second embodiment of a valve device, wherein the magnet arrangement is arranged on the outside of the channel and the first and second coupling arrangement form a pivot bearing,
• 5 a schematic top view of a third embodiment of a valve device, wherein the first and second coupling arrangement are rotatably coupled to one another,
• 6th a schematic side view of the in 5 shown third embodiment of a valve device,
• 7th a schematic side view of a fourth embodiment of a valve device, wherein the valve body comprises sealing lips and the superconductor arrangement is embedded in the duct wall,
• 8th a schematic plan view of the in 7th shown fourth embodiment of a valve device.

In the following description of the figures, the same designations are used for functionally identical components of the illustrated embodiments, with multiple descriptions of functionally identical components being dispensed with.

1 to 3 show schematically a first embodiment of a valve device according to the invention 10 which is a section of an exemplary tubular channel 2 and one in the canal 2 arranged valve body 5 includes. 1 and 2 show a top view of the valve device 10 , while 3 a side view of the valve device 10 shows.

In the figures is the valve body 5 shown by way of example in an elongated cuboid shape. Of course, the valve body 5 but also have any other shape with which the valve body is pivoted 5 in the canal 2 influencing a free cross section of the channel 2 is possible. For example, the valve body 5 be formed in any shape other than a perfect sphere.

The valve body 5 can by pivoting around the graphically represented, physically non-existent axis of rotation 8th be moved from a first position to a second position. The axis of rotation 8th runs perpendicular to a fluid flow in this example 3 , but it can also be oriented differently. The orientation is preferably the axis of rotation 8th from the direction of fluid flow 3 different. 1 shows the valve body 5 in an exemplary first position, in which the longitudinal side of the valve body 5 in the direction of the fluid flow 3 is aligned so as to reduce the free cross-section of the channel 2 normal to fluid flow 3 to maximize. 2 shows the valve body 5 in its second position. The long side of the valve body is in this second position 5 no longer in the direction of the fluid flow 3 aligned so that the free cross section of the channel 2 is now smaller than in the first position. As in 2 shown, the valve body 5 in the second position on the canal 2 so that it is stable. Alternatively, the valve body 5 in the second position of the canal 2 be kept spaced. It is also possible that the long side of the valve body 5 is shorter than the longest dimension or the diameter of the channel cross-section, so that the valve body 5 can also assume a position in which the longitudinal side of the valve body 5 perpendicular to the direction of fluid flow 3 stands.

In the 1 to 3 is the channel 2 shown in elongated tubular shape. The cross-section of the channel, not shown 2 can be designed accordingly depending on the application. For example, the cross section of the channel 2 be circular, oval, or rectangular. Of course, the channel can 2 also be designed in any other form in which it is possible by means of a pivoting of the valve body 5 a free cross-section of the channel 2 to influence.

The channel 2 is suitable a fluid 3 respectively. In 1 becomes an exemplary flow direction of the fluid 3 by the reference number 3 indicated arrows.

As in 3 shown, the valve body 5 the second coupling arrangement 6th comprise and a number of magnet assemblies 12 exhibit. In the embodiment shown, there are two magnet arrangements 12 intended; however, only one magnet arrangement can expediently be used 12 or more than two magnet arrangements can be provided. Preferably, the magnet arrangements 12 on the end faces of the valve body 5 be arranged so as to reduce the distance between the magnet assemblies 12 and the superconductor arrangements designed as the first coupling arrangement 13 to minimize like this in 3 is shown. In order to provide an essentially circularly symmetrical magnetic field or a section thereof, the magnet arrangements 12 as in 1 shown consist of concentrically arranged cutouts of circularly symmetrical permanent magnets. For example, corresponding sections of ring magnets can be used here. Of course, entire ring magnets can also be used instead of the cutouts shown. If there are several magnet arrangements 12 are provided, they can preferably be arranged coaxially to one another, so that the axes of symmetry of the respective magnet arrangements 12 essentially lie on a straight line, thus also the entirety of magnet arrangements 12 has an essentially circularly symmetrical characteristic and is therefore well suited for this, together with one or more superconductor arrangements 13 to form a pivot bearing. In the present embodiment, the axes of symmetry of the two magnet arrangements lie 12 on a straight line, which interacts with the correspondingly arranged superconductor assemblies 13 a pivot bearing with the axis of rotation 8th is formed.

Like in the 3 shown, both end faces of the valve body touch 5 the inner wall of the channel 2 . Alternatively, the valve body 5 also be dimensioned in this way and / or in the channel 2 be arranged that one or both end faces of the valve body 5 are spaced from the inner duct wall. In particular, the valve body 5 so dimensioned and / or in the channel 2 be arranged that in one, both or all positions, the inner wall of the channel 2 not touched. Preferably on the valve body 5 or one or more sealing lips can be attached to its end faces. Like in the 3 shown are the magnet arrangements 12 in the present embodiment in the end faces of the valve body 5 let in. Alternatively, the magnet arrangements 12 but also on the end faces of the valve body 5 be put on. It is also possible that the entire valve body 5 as a magnet assembly 12 is trained.

As in the 3 shown comprises the coupling arrangement 4th two superconductor assemblies 13 , each designed as a plate-shaped superconductor and on the outside of the channel 2 are arranged. Alternatively, only one superconductor arrangement can be used 13 or more than two superconductor assemblies 13 be provided. The superconductor arrangements 13 can also be on the outside of the canal 2 fixed or detached from the canal 2 be arranged. The superconductor arrangements 13 can be arranged such that a movement of the superconductor assemblies 13 relative to the channel 2 is made possible. In addition, the superconductor arrangements 13 also in the wall of the canal 2 be let in so as to reduce the distance between the superconductor assembly 13 and magnet arrangement 12 to minimize. The superconductors can preferably be cooled to or below their critical temperature by a cooling device not shown here, such as a cryostat or a cooling body containing liquid nitrogen.

So that between the superconductor arrangements 13 and the magnet assemblies 12 results in the above-described magnetic coupling, a magnetic field geometry is stored in each of the superconductors which essentially corresponds to the geometry of the magnetic field penetrating the superconductor. In particular, the axis of symmetry of the magnetic field geometry stored in the superconductors is essentially coaxial with that of the magnet arrangements 12 provided magnetic fields. This enables the formation of a pivot bearing in which the axis of rotation 8th essentially with the symmetry axes of the magnetic fields of the magnet arrangements 12 and the stored magnetic field geometries match. Accordingly, there is essentially no change in the magnetic interaction between the magnet arrangements 12 and the superconductor assemblies 13 upon rotation of the valve body 5 around the axis of rotation 8th on.

In the first embodiment, the valve device comprises 10 further a first drive means 7th , which is used for the contactless provision of an actuating force on the valve body 5 is set up to this relative to the channel 2 to pivot between a first position and a second position. In the present embodiment, the drive means is 7th arranged or designed in such a way that the actuating force is essentially perpendicular and skewed to the axis of rotation 8th as well as perpendicular to the longitudinal direction of the channel 2 is aligned. Ultimately, however, any other alignment of the actuating force that affects the valve body is also possible 5 with a torque around the axis of rotation 8th applied and so a corresponding pivoting of the valve body 5 around the axis of rotation 8th can cause.

In the present embodiment, the drive means is 7th designed to provide a magnetic field. The main direction of this magnetic field is preferably aligned parallel to the largest surface of the plate-shaped superconductor in order to minimize the interaction between this magnetic field and the superconductors. The magnetic field penetrates at least one component 9 of the valve body 5 , which has magnetic properties, so that by the provided magnetic field of the drive means 7th the component 9 is applied with the actuating force. The component can expediently 9 the magnet arrangement 12 include. Depending on the magnetic properties of the component 9 and alignment of the provided magnetic field can be an attractive or repulsive force between the component as the actuating force 9 and the drive means 7th be effected. In the present embodiment, it is sufficient if the actuating force can only be exerted in one direction around the valve body 5 to pivot from the first position to the second position. The return to the first position can then take place by weakening or switching off the magnetic field of the drive means, since the valve body 5 also from the fluid flow due to its elongated geometry 3 can be moved back to the first position. However, it is of course also possible to bring about the return from the second position to the first position in that the drive means 7th provides a corresponding actuation force.

The drive means 7th can be controlled by a control unit not shown in the figures and provide the actuating force or the magnetic field causing the actuating force as a function of a control signal output by the control unit.

4th shows a schematic plan view of a second embodiment of a valve device according to the invention 20th . In contrast to the first embodiment, here are the superconductor arrangements 13 the valve body 5 assigned, and the magnet assemblies 11 the channel 2 assigned. The channel preferably leads here 2 a fluid 3 that is cold enough to make the superconductor assemblies 13 to cool to or below their transition temperature. For example, the channel 2 as a fluid 3 lead liquid nitrogen.

In this second embodiment, the magnet arrangements 11 be designed as electromagnet arrangements or permanent magnet arrangements.

As in the first embodiment, the number of magnet arrangements in the second embodiment 11 and superconductor assemblies 13 each smaller or larger than two. In addition, in the second embodiment, the magnet arrangements 11 outside of the channel, outside of the channel, or in the wall of the channel. The superconductor arrangements 13 can, as in 4th shown on the end faces of the valve body 5 attached or embedded in this. The alignment of the magnetic fields of the magnet assemblies 11 to the stored magnetic field geometries in the superconductor arrangements 13 corresponds to the orientation already discussed in connection with the first figure and should not be repeated at this point.

In addition, the valve body can also in the second embodiment 5 be dimensioned in this way and / or in the channel 2 be arranged that one or both end faces of the valve body 5 are spaced from the inner duct wall. In particular, the valve body 5 so dimensioned and / or in the channel 2 be arranged that in one, both or all positions, the inner wall of the channel 2 not touched. Preferably on the valve body 5 or one or more sealing lips can be attached to its end faces.

The 5 and 6th show a third embodiment. In contrast to the first and second embodiment, the coupling arrangements here do not form a rotary bearing, but are coupled to one another in a rotationally fixed manner. In the 5 and 6th This aspect is indicated by the fact that the first and second coupling arrangements are particularly elongated, so that the magnetic field provided by the magnet arrangement and the magnetic field geometry stored in the superconductor arrangement are not circularly symmetrical, whereby the second coupling arrangement 6th when pivoting the first coupling arrangement 4th experiences corresponding forces that the second coupling arrangement 6th force the pivoting of the first coupling arrangement 4th to follow. For pivoting the first coupling arrangement 4th can here the drive means 7th comprise a rotary motor which transmits a corresponding torque to the first coupling arrangement via a drive shaft 4th brings up. Alternatively, the first coupling arrangement can of course also be used 4th are kept stationary, and the channel 2 be pivoted by means of a corresponding drive means so as to pivot the channel 2 relative to the valve body 5 to achieve.

Analogous to those in the 3 and 4th The permutations shown can also be the superconductor arrangements and magnet arrangements of the channel 2 or the valve body 5 be assigned and arranged or attached in a manner already discussed in connection with the previous embodiments.

In addition, in the third embodiment, the valve body 5 be dimensioned in this way and / or in the channel 2 be arranged that one or both end faces of the valve body 5 are spaced from the inner duct wall. In particular, the valve body 5 so dimensioned and / or in the channel 2 be arranged that in one, both or all positions, the inner wall of the channel 2 not touched. Preferably on the valve body 5 or one or more sealing lips can be attached to its end faces.

The 7th and 8th show a fourth embodiment of a valve device 40 . The fourth embodiment corresponds essentially to the first embodiment and a repeated explanation of the functionally identical components is avoided at this point. The valve device 40 in this embodiment also has sealing lips 14th as well as cooling devices 15th on. Of course, these additional features can also be used in each of the first to third embodiments of the valve device according to the invention already discussed.

Claims (10)

Valve device (10; 20; 30; 40) comprising: a channel (2) for guiding a fluid (3), a valve body (5) which is arranged in the channel (2), a first coupling arrangement (4), the associated with the channel (2), and a second coupling arrangement (6) associated with the valve body (5), one of the two coupling arrangements comprising a magnet arrangement (11; 12) and the other of the two coupling arrangements comprising a superconductor arrangement (13) , and the magnet arrangement (11; 12) and the superconductor arrangement (13) are coupled to one another in a contactless force-transmitting manner in order to ensure a pivotable mounting of the valve body (5) relative to the channel (2), a drive means (7) for providing an actuating force to the Valve body (5) in order to pivot this relative to the channel (2) between a first position and a second position and thereby to influence a free cross section of the channel (2). Valve device (10; 20; 40) according to Claim 1 , the first and second coupling arrangements (4, 6) forming a pivot bearing with an axis of rotation (8) for the valve body (5) so that the valve body (5) is pivoted about the axis of rotation (8) when the coupling arrangements move relative to one another . Valve device (10; 40) according to Claim 1 or 2 wherein the second coupling arrangement (6) as the magnet arrangement (12) comprises at least one circularly symmetrical permanent magnet and / or at least one section of a circularly symmetrical permanent magnet. Valve device (20) according to Claim 1 or 2 wherein the first coupling arrangement (4) comprises an electromagnet arrangement and / or a permanent magnet arrangement as the magnet arrangement (11). Valve device (10) according to one of the Claims 1 to 4th wherein the drive means (7) is set up to provide a magnetic field which at least partially penetrates the valve body (5) as a function of a control signal. Valve device (10; 20) according to Claim 5 wherein at least one component (9) of the valve body (5) has magnetic properties, so that the magnetic field provided by the drive means (7) exerts the actuating force on the valve body (5). Valve device (30) according to Claim 1 , wherein the first coupling arrangement (4) and the second coupling arrangement (6) are rotatably coupled to one another, and the drive means (7) is set up to pivot the first coupling arrangement (4) relative to the channel as a function of a control signal in order to prevent the pivoting of the To effect valve body (5). Valve device (10; 20; 30; 40) according to one of the Claims 1 to 7th wherein the superconductor arrangement (13) comprises at least one plate-shaped superconductor which is at least partially arranged within a magnetic field provided by the magnet arrangement (11; 12). Valve device (10; 20; 30; 40) according to one of the Claims 1 to 8th , wherein the valve body (5) rests against the channel (2) in the first position and / or the second position, so that the valve body is mounted in a stable manner in the first position and / or the second position. Valve device (10; 20; 30; 40) according to one of the Claims 1 to 9 , wherein the valve body (5) comprises at least one sealing lip (14) which rests against the channel (2) in the first and / or second position so that the channel (2) is closed in one of the two positions.

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